Magnetic disk drive

ABSTRACT

In order to achieve narrow track pitch by measuring, storing and compensating common average values for repeatable runout components between adjacent tracks in a head positioning control system for a magnetic disk drive, there are provided: means for calculating a compensated signal for the average value of the repeatable runout of each servo sector of at least two tracks of servo information reproduced from a magnetic disk, on the basis of an inverse function of the sensitivity characteristics of the tracking control system; means for storing the calculated signal; and means for compensating the servo signal on the basis of this signal.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to magnetic head positioning means for amagnetic disk drive, and more particularly, to magnetic head positioningmeans for a sector servo system magnetic disk drive wherein servoinformation is recorded on a magnetic disk before being incorporatedinto a magnetic disk drive.

2. Description of the Related Art

Conventionally, servo information is stored onto a magnetic disk afterthe magnetic disk has been installed in a magnetic disk drive.Accordingly, there has been a requirement for magnetic disk drives tohave a function for performing high-precision servo informationrecording, in order to meet demands for narrowing of servo tracks. As aresult, it is necessary to provide a high-precision positioningmechanism and hence the magnetic disk drive becomes expensive.

On the other hand, one technique for improving positioningcharacteristics in order to achieve narrowing of servo tracks is asystem as disclosed in Japanese Patent Laid-open No. (Hei)9-282820 whichcompensates for the repeatable runout components in the servo signalwhich are generated when servo information is written to a magneticdisk. In this conventional compensating system, the repeatable runoutcomponents are measured and compensated for.

However, in order to counteract repeatable runout components caused bythe excitation of the spindle motor which rotates the magnetic disk, orby deformation of the magnetic disk, these components being particularlynotable when servo information is recorded onto the magnetic disk bymeans of this system before installing the disk in a magnetic diskdrive, a large memory space is required because of the need to storecompensation values for a large number of tracks.

SUMMARY OF THE INVENTION

The system which measures and stores repeatable runout components foreach servo sector as disclosed in the prior art is not desirable withregard to achieving an inexpensive magnetic disk drive, since itrequires a large memory volume to store the information used incompensating the repeatable runout components across all servo tracks.

It is also possible to conceive of a system wherein specific track datais stored in order to restrict the memory volume used to store therepeatable runout compensation values, but this is not desirable fromthe viewpoint of improving location accuracy, as the repeatable runoutcomponents generally vary between different tracks.

Therefore, the present invention provides a magnetic disk drive havingmeans for positioning a magnetic head in a highly accurate manner, bycompensating for the average value of repeatable runout components whichare particularly notable when servo information is recorded to amagnetic disk before the disk is installed in a magnetic disk drive.

In order to resolve the aforementioned problem, the present invention isa magnetic disk drive comprising means for measuring the average valueof the repeatable runout components for each servo sector across atleast two or more tracks, and means for removing repeatable runoutcomponents from the servo information on the basis of this measurementvalue, or means for adjusting the slice level used to judge when to haltdata recording, if there is a large error in positioning during datarecording.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing one embodiment of the present invention;

FIG. 2 is an algorithm for measuring a compensation value for theaverage value of repeatable runout according to the present invention;

FIG. 3 is an explanatory diagram of a measurement zone for thecompensation value for the average value of repeatable runout accordingto the present invention;

FIG. 4 is a block diagram of tracking control system for recording orreproducing data according to the present invention;

FIG. 5 is a diagram showing example results of repeatable runoutmeasurement in a case where the present invention is, not applied;

FIG. 6 is a diagram showing calculation results for the compensationvalue for the average value of repeatable runout;

FIG. 7 is a diagram showing servo signal measurement example results ina case where the present invention is not applied;

FIG. 8 is a diagram showing a further embodiment; and

FIG. 9 is a diagram showing yet a further embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 shows one embodiment of the present invention. An overview of thepresent invention is described on the basis of FIG. 1. A magnetic disk101 storing servo information and data is attached to a spindle motor102 and incorporated into a magnetic disk drive. A servo pattern (notillustrated) is recorded onto the magnetic disk 101 by means of servopattern recording apparatus (not illustrated) prior to attaching themagnetic disk 101 onto the spindle motor 102.

A servo signal 108 is obtained as a result of the servo pattern recordedon the magnetic disk 101 being read out by means of a magnetic head 103.Here, the servo signal 108 comprises positional information indicatingthe position of the magnetic head 103 over the magnetic disk 101. Inother words, it is constituted by a grey code indicating the number of a“track”, tracks being concentrically shaped regions on the magnetic disk101 having an approximately uniform width in the radial direction(integers being assigned consecutively from the outer circumference tothe inner circumference of the magnetic disk 101 as a track number for aradially consecutive plurality of tracks), and a position error signalindicating deviation from the centre of the track.

A positional error signal 116 obtained by means of an adder 118differentiating the position information obtained from the servo signal108, from the target position information indicated by a mastercontroller 111, is added by an adder 106 to a repeatable runout averagevalue compensation signal 109 previously measured and recorded by arepeatable runout average value compensator 107. The servo information110 thus obtained is input to the compensator 105. The compensator 105derives a servo control signal 117 and locates the magnetic head 103 inthe target position instructed by the master controller 111 of themagnetic disk 101, by driving a magnetic head support system 104 via adrive system 115. Positioning means is constituted jointly by thecompensator 105, drive system 115 and magnetic head support system 104.

The present embodiment discloses a system for adding a repeatable runoutaverage value compensation signal 109 to a position error signal 116,but in a digital control system where the servo signal forming the mainsignal of the magnetic disk servo system is handled as digitalinformation in the processor, the present invention can be implementedreadily by means of composition wherein a repeatable runout averagevalue compensation value 109 is added to the servo signal.

Next, the operation of the repeatable runout average value compensator107 is described. This repeatable runout average value compensator 107is constituted by a compensation value measuring function 112, acompensation value recording function 113 and a compensation valueoutput function 114. The compensation value measuring function 112operates according to the flowchart shown in FIG. 2, on the basis of arepeatable runout average value compensation value measurement operationinstruction from the master controller. Here, in the processing fordeducing a repeatable runout average value compensation value accordingto the flowchart in FIG. 2, the repeatable runout average valuecompensation signal 109 in FIG. 1 is set to zero.

Firstly, head #0 is selected (s101). The sequence then moves to aprocess for determining whether the selected head is lower than themaximum head number (s102). If the selected head number is greater thanthe maximum head number at this head number judgement process (s102), inother words, if compensation value measurement has been completed forall the heads, then the compensation value measuring function 112terminates. If, on the other hand, the selected head number is equal toor less than the maximum head number, in other words, if measurement hasnot been completed for all the heads, then the sequence transfers to aprocess for determining whether the compensation value measurement zoneis smaller than the maximum measurement zone (s103).

Here, a “compensation value measurement zone”, as illustrated in FIG. 3,corresponds to a repeatable runout compensation area (303, 304) obtainedby dividing the data storage area 302 of the magnetic disk 101 in theradial direction thereof. If the measurement zone is judged to begreater than the maximum zone as a result of the judgement process ats103, then the sequence shifts to a process for incrementing themeasurement head number (s104), and then branches to the head numberjudgement process at s102. If, on the other hand, the measurement zonenumber is equal to or less than the maximum zone number, then thesequence shifts to a process (S105) for determining whether themeasurement track number (number of tracks) is less than the maximumtrack number (number of tracks) in that measurement zone.

Here, when the repeatable runout average value compensation valuemeasurement operation instruction is given by the master controller, themeasurement zone number where measurement is to be started is determinedas an initial setting, similarly to the head at S101, and the head ismoved to the determined measurement zone. It is then possible to measurea prescribed number of zones by setting the measurement zone number atwhich measurement will terminate to the maximum zone number.

If the measurement track number is greater than the maximum track number(number of tracks) in that measurement zone (where number of measurementtracks in the zone is taken as n), then the average value of themeasured repeatable runout for the n tracks is calculated (s108). Acompensation value for this repeatable runout average value is thencalculated by means of a method described hereinafter (s109).Subsequently, this calculation result is stored in a non-volatilestorage area by means of the compensation value storing function 113(s110). Here, this non-volatile storage area is taken to be a memorysuch as an EPROM mounted on a circuit board (not illustrated), or astorage area of the magnetic disk 101. When the process of storing thecompensation value in the non-volatile memory (s110) has been completed,the measurement zone number is incremented (sill), and the sequencebranches to the process for determining whether the measurement zonenumber is equal to or less than the maximum zone number (s103).

If, on the other hand, the measurement track number (number of tracks)is equal to or less than the maximum track number (number of tracks=n),then the sequence branches to a process (s106) for measuring therepeatable runout component for each servo sector (servo pattern storageregions distributed in approximately equilateral fashion within tracks)from the position error signal 116 obtained by differentiating theposition information derived from the servo signal 108, from the targetposition information instructed by the master controller 111.

The repeatable runout components are derived by storing theaforementioned position error signal 116 in the memory for each mcycles, and averaging same for each servo sector. The aforementionedposition error signal 116 is defined as PES[i][r] (where i: servo sectornumber 1˜sect; r: measurement frequency 1˜m). In this case, therepeatable runout component RRO[i] (repeatable runout component forservo sector number i) is given byRRO[i]=(1/m)(PES[i][1]+PES[i][2]+ . . . +PES[i][m])  (equation 1)

When the process for measuring the repeatable runout components (s106)in the track in question has been completed, the measurement tracknumber (number of tracks) is incremented (s107), and the sequencetransfers to the process for determining whether the measurement tracknumber (number of tracks) is equal to or less than the maximum tracknumber (number of tracks) (s105).

Here, similarly to the measurement zone number described above, a tracknumber for starting measurement is previously stipulated, and the headis moved to the corresponding track. It is possible to measurecompensation values for a prescribed number of tracks by stipulating thetrack number where measurement is to terminate as the maximum tracknumber.

Whilst it is necessary to perform measurement for all of the heads, itis not required to measure compensation values for all zones or, inparticular, all tracks. It is possible to achieve the effects of thepresent invention provided that compensation values are measured for atleast a plurality of tracks in one zone.

Next, the method for calculating repeatable runout compensation valueswill be described.

FIG. 4 illustrates the system in FIG. 1 by converting same to agenerally known format, called a block diagram. Firstly, the targetposition information instructed by the master controller 111 and theservo information 108 are added together by the adder 118. Thereupon,the adder 106 adds the repeatable runout average value compensationsignal 109 read out from the repeatable runout average value compensator107 to the position error signal 116 output by the adder 118. On thebasis of the output from this adder 106, namely, the servo information110, the compensator 105 (having transmission characteristics of Gc(z))calculates a servo control signal 117 and implements positional controlof the magnetic head support system by means of the drive system 115(the transmission characteristics of the drive system and the headsupport system being taken as Gp(z) and being represented by a singleblock 401). Here, z indicates a well-known z transform operator.

Here, the servo sector number is taken as sect, the number of heads istaken as hd, the number of measurement zones is taken as zone, and thenumber of measurement tracks in each measurement zone is taken as track.The repeatable runout component for the (i)th servo sector (i=1˜sect) ofthe (j)th track (j=1˜track) of the nth zone (n=1˜zone) of the (m)th head(m=0˜hd-1) is determined as RRO[m][n][i][j] by the processing at s106.Here, the repeatable runout average value compensation signal RRO_COMP[m][n][i] is not added to the position error signal 116 used whencalculating the repeatable runout components. When measurement of therepeatable runout for the number of measurement tracks has beencompleted for a particular measurement zone, the average thereof RRO_AVGis calculated (equation 2).RRO _(—) AVG[m][n][i]=(1/track)×{RRO[m][n][i][1]+ . . .+RRO[m][n][i][track]}  (equation 2)

The repeatable runout average value compensation value RRO_COMP[m][n][i]is derived as follows from the repeatable runout average valueRRO_AVG[m][n][i], the compensator transmission characteristics (105)Gc(z), and the drive system and magnetic head support systemtransmission characteristics (401) Gp(z):RRO _(—) COMP[m][n][i]={1+Gc(z)×Gp(z)}×RRO _(—) AVG[m][n][i]  (equation3)

Adding the compensation value from equation 3 to the position errorsignal 116 cancels out the average value of the repeatable runoutcomponent (for the relevant measurement zone) contained in the servosignal 108 read from the magnetic disk 101. Furthermore, the repeatablerunout average value compensation value determined by the calculation inequation 3 is recorded by the compensation value storing function 113.When data is recorded or reproduced by means of the magnetic head 101following an indicated track, processing is implemented whereby thecompensation value output function 114 reads out the compensation valuefrom the compensation value storing function 113, on the basis of themeasurement zone, head and sector information, and adds same to theposition error signal 116.

FIG. 5 illustrates the results of measuring servo informationPES_COMP(Z) at the inner, central and outer positions of the measurementzone (1), in the tracking control system in FIG. 4, where the repeatablerunout average value compensation signal RRO_COMP[m][n][i] is taken as 0(in other words, where no compensation is implemented). Moreover, FIG. 6illustrates a repeatable runout average value compensation signalderived from equation 3. Furthermore, FIG. 7 shows the results ofcompensating the signal in FIG. 5 by means of the compensation signal inFIG. 6. Positioning accuracy is improved greatly by compensating theaverage value of the repeatable runout.

FIG. 8 shows a further embodiment. This involves functions performingdifferent operations to those in the embodiment shown in FIG. 1. Thecompensation value measuring function 112 constituting the repeatablerunout average value compensator 107 terminates its operation at thecalculation of the repeatable runout average value RRO_AVG[m][n][i] inequation (2). This repeatable runout average value RRO_AVG[m][n][i] isthen stored in the compensation value storing function 113. Similarly tothe embodiment shown in FIG. 1, the compensation signal read out by thecompensation value output function 114 is input to a data write prohibitjudgement section 801.

In the data write prohibit judgement section 801, a data write prohibitoperation is judged, according to the compensation signal read out fromthe compensation value output function 114 (repeatable runout averagevalue), the position error signal 116, and the data write position errortolerance, and a data write prohibit instruction is sent to the HDC(hard disk controller) 802. Generally, data write prohibit isimplemented when the position error signal 116 is greater than aprescribed value, in order to restrict the distance between the centraldata positions of adjacent tracks to a prescribed distance range. Inother words, the data write prohibit judgement section 801 comprises apositioning error slice level used to judge when to suspend datarecording if the positioning error is large during data recording, or afunction for adjusting the position error information used whenperforming such judgement. This positioning error slice level is storedpreviously in a non-volatile memory or on the magnetic disk 101.Furthermore, the positioning error slice level and positioning errorinformation are adjusted for each servo sector.

Here, the repeatable runout average value is the same value betweencontinuous tracks. In other words, the path of the magnetic head 103with respect to the repeatable runout average value according to thetracking servo system is the same between consecutive tracks. Therefore,in order to maintain the distance between central data positions ofadjacent tracks recorded along this path within a prescribed distancerange, the data write prohibit off-track amount should be adjusted tofollowing this path. In other words, the data write prohibit off-trackamount WF[i] according to the present invention (where i: servo sectornumber 1˜sect) should be set as follows, according to the repeatablerunout average value RRO_AVG[m][n][i] (equation 1) and the data writeposition error tolerance WF_SLICE (a uniform value indicating thetolerated off-track amount when the average repeatable runout value iszero).WF[i]=WF_SLICE+RRO_AVG[m][n][i]  (equation 4)

The data write prohibit off-track amount WF[i] adjusted in this manneris compared with the position error signal 116 (denoted as PES[i]), andby prohibiting data writing ifPES[i]>WF[i]  (equation 5)

-   -   it is possible to restrict the distance between the central        positions of data recorded onto adjacent tracks, within a        uniform range.

Furthermore, rather than adjusting the data write prohibit off-trackamount according to the repeatable runout RRO_AVG[m][n][i] as describedabove, it is also possible to adjust the position error information towhich the data write prohibit off-track amount is compared. In otherwords, the position error information is adjusted toPES _(—) COMP[i]=PES[i]−RRO _(—) AVG[m][n][i]  (equation 6)

-   -   and the data write prohibit judgement condition is set to        PES_COMP[i]>WF_SLICE  (equation 7)

FIG. 9 shows a block diagram of a further embodiment of the presentinvention. In this embodiment, rather than compensating the servosignal, the average value of the control signal sent to the positioningmeans is compensated.

The compensator 105 (having transmission characteristics of Gc(z))derives a servo control signal 117 on the basis of the sum of the servosignal 108 and the target position information instructed by the uppercontroller 111, as output by the adder 118. Adder 106 then adds arepeatable runout average value compensation signal 901, as read outfrom the repeatable runout average value compensator 107, to signal 117,to yield a control signal 902, which is used as a basis to control thepositioning of the magnetic head support system (the transmissioncharacteristics of the drive system and the head support system beingtaken as Gp(z) and being represented by a single block 401). Here, zindicates a well-known z transform operator.

The repeatable runout average value compensation signal 901RRO_COMP2[m][n][i] is determined by (equation 8).RRO _(—) COMP2[m][n][i]={1/Gp(z)}×RRO _(—) AVG[m][n][i]+ACC _(—)AVG[m][n][i]  (equation 8)

ACC_AVG[m][n][i] is the average value of the control signal for eachservo sector of a plurality of tracks, and hereACC _(—) AVG[m][n][i]=(1/track)×{ACC[m][n][i][1]+ . . .+ACC[m][n][i][track]}  (equation 9)

ACC[m][n][i][j] indicates the input to the drive system 401, in otherwords, the output from the compensator 105, for the (m)th head(m=0˜hd-1), nth zone (n=1˜zone), (j)th track (j=1˜track) and (i)th servosector (i=1˜sect), when no repeatable runout average value compensationis performed. In this embodiment, the magnetic head 103 operates so asto follow the repeatable runout average value. Therefore, the effect ofthe repeatable runout average value is removed from the servo signal 108and hence positioning accuracy is improved.

The average value of the drive signal 902 when no repeatable runoutaverage value compensation signal 901 is input is defined as the averagecontrol signal.

In each of the foregoing embodiments, the repeatable runout wasdetermined, the average value thereof was derived and a compensationvalue was calculated, with respect to all sectors, all tracks and allheads, but this is not a mandatory condition. With regard to the heads,the repeatable runout should be determined for at least one of theheads. With regard to tracks, the repeatable runout should be determinedand a compensation value calculated, for at least a plurality of tracksin the same sector. With regard to the sectors, similarly, there is noneed to determine the repeatable runout for all sectors, and it ispossible to calculate a compensation value by, for example, determiningthe repeatable runout for half the sectors by selecting alternatesectors, or determining the repeatable runout in only three or fourpositions of one cycle of a track.

According to the present invention, the accuracy of positioning amagnetic head is improved by compensating the average value of therepeatable runout. Therefore, it is possible to improve the positioningaccuracy of a magnetic disk drive which utilizes a system where servoinformation is recorded onto the magnetic disk before installing themagnetic disk on the spindle motor, this system tending to produceparticularly notable worsening of positioning accuracy due to theaverage value of repeatable runout.

1-11. (canceled)
 12. A magnetic disk drive comprising: a magnetic diskhaving a plurality of tracks on which serve information is stored; amagnetic head for recording/reproducing information to/from saidmagnetic disk; and a supporter for supporting and positioning saidmagnetic head over said magnetic disk; wherein said supporter isadjustable on the basis of the average value of the repeatable runoutfor servo sectors in a plurality of different tracks.
 13. The magneticdisk drive according to claim 12, wherein the adjustment of saidsupporter is performed by means for compensating the servo signal. 14.The magnetic disk drive according to claim 13, wherein a servo signalcompensation value based on said average value of the repeatable runoutis stored in a non-volatile memory or on said magnetic disk.
 15. Themagnetic disk drive according to claim 12, further comprising acompensator for compensating the control signal to said supporter, onthe basis of the average control signal to said supporter for each servosector of a plurality of tracks, and the average value of the repeatablerunout for each servo sector in a plurality of tracks.
 16. The magneticdisk drive according to claim 12, wherein said average value of therepeatable runout is calculated on the basis of positional errorsignals.
 17. The magnetic disk drive according to claim 12, wherein saidsupporter is adjusted on the basis of a compensation value correspondingto a plurality of zones divided in a radial direction of said magneticdisk, and said compensation value is calculated on the basis of therepeatable runout.
 18. A magnetic disk drive comprising: a magnetic diskhaving a plurality of zones divided in the radial direction of saidmagnetic disk, each of said zones having a plurality of tracks; amagnetic head for recording/reproducing information to/from saidmagnetic disk; a supporter for supporting and positioning said magnetichead over said magnetic disk; and a compensator for compensating signalsfor controlling said supporter; wherein said compensator compensatessaid signals on the basis of compensation values corresponding to eachof said zones.
 19. The magnetic disk drive according to claim 18,wherein said signals are servo signals read from said magnetic disk bysaid magnetic head.
 20. The magnetic disk drive according to claim 18,wherein each of said compensation values is calculated on the basis of arepeatable runout average value of each of said zones.
 21. The magneticdisk drive according to claim 20, wherein said repeatable runout averagevalue is the average value of the synchronous vibration for servosectors in a plurality of tracks of each of said zones.
 22. The magneticdisk drive according to claim 18, wherein said compensation values arestored in a non-volatile memory or on said magnetic disk.
 23. Themagnetic disk drive according to claim 20, wherein said repeatablerunout average values are stored in said non-volatile memory or on saidmagnetic disk.